Simple models for tensile modulus of shape memory polymer nanocomposites at ambient temperature

Yasser Zare,Fatemeh Molaabasi,Kyong Yop Rhee

doi:10.1515/ntrev-2022-0053

Yasser Zare, Fatemeh Molaabasi + Show 1 more

Open Access

https://doi.org/10.1515/ntrev-2022-0053

Copy DOI

Abstract

Abstract This article analyzes the tensile modulus of shape memory polymer nanocomposites (SMPNs) at ambient temperature. Several conventional models, such as rule of mixtures, Halpin–Tsai and Kerner–Nielsen, cannot practically estimate the modulus due to the absence of some main parameters for nanocomposites. Additionally, some parameters in Kerner–Nielsen and Sato–Furukawa models are useless and ineffective, due to the small concentration and high modulus of nanofillers in SMPNs. Therefore, Kerner–Nielsen and Sato–Furukawa models are simplified and modified to deliver the simple models for calculation of modulus in SMPNs. Various nanocomposite samples are provided to prove the validity of the suggested models. The results demonstrate that the predictions of the suggested models have a good match with the experimental results. The models also demonstrate high simplicity and good accuracy for the calculation of modulus in SMPNs at ambient temperature. Generally, the calculated results disclose that the modified Kerner–Nielsen model is preferable for approximation of modulus in SMPNs.

Highlights

This article analyzes the tensile modulus of shape memory polymer nanocomposites (SMPNs) at ambient temperature
The mentioned models are evaluated using the experimental results of many SMPNs containing different matrices and nanofillers from literature
An attempt is made to simplify the models for modulus of SMPNs at ambient temperature

Summary

Introduction

Abstract: This article analyzes the tensile modulus of shape memory polymer nanocomposites (SMPNs) at ambient temperature. The elastic modulus of an SMP increases by addition of nanofillers [43,44,45,46,47,48], but there is no efficient model to calculate the modulus of SMPNs. SMPNs store the mechanical energies at elevated temperatures and release them in response to external stimulus. We assume the original status of shape memory nanocomposites to be below Tg, because the modulus of samples decreases at elevated temperatures after Tg. The modulus of SMPNs at ambient temperature can reveal the capability of samples for converting the stored energy to force. This work provides a simple methodology for estimation of tensile modulus of SMPNs to guide researchers in this field

Micromechanics models

Results and discussion

Conclusion